molecular characterization of fermenting yeast species from fermented...
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Research ArticleMolecular Characterization of Fermenting YeastSpecies from Fermented Teff Dough during Preparation ofInjera Using ITS DNA Sequence
Belay Tilahun Tadesse ,1 Andualem Bahiru Abera,2 Anteneh Tesfaye Tefera ,3
Diriba Muleta ,3 Zewdu Terefework Alemu,4 and GaryWessel5
1Wolkite University, Collage of Natural and Computational Science, Biotechnology Department, Ethiopia2Addis Ababa Institute of Technology, Addis Ababa University, Ethiopia3Institute of Biotechnology, Addis Ababa University, Ethiopia4MRC-ET Molecular Diagnostics, Addis Ababa, Ethiopia5Department of Molecular Biology, Cellular Biology and Biochemistry, Brown University, Providence, RI 02912, USA
Correspondence should be addressed to Belay Tilahun Tadesse; [email protected]
Received 15 February 2019; Accepted 7 April 2019; Published 1 July 2019
Academic Editor: Alejandro Castillo
Copyright © 2019 Belay Tilahun Tadesse et al. This is an open access article distributed under the Creative Commons AttributionLicense, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properlycited.
Identification of the yeast responsible for Injera fermentation is important in order to be more consistent and for scale-up ofInjera production. In this study, yeast were isolated and identified from fermenting teff dough sample collected from household,hotels, and microenterprises, Addis Ababa. Initially, the yeast obtained from fermenting teff dough of different sources wereselected on the basis of their CO
2production potentials. Its DNA sequencing of isolated yeast identified Pichia fermentans,
Pichia occidentalis, Candida humilis, Saccharomyces cerevisiae, andKazachstania bulderi.The association of identified yeast to theirsources indicated the presence of Pichia fermentans in fermenting dough samples collected from all sources whereas Kazachstaniabulderi, Saccharomyces cerevisiae, and Candida humiliswere shown to be present in samples collected from households, hotels, andmicroenterprises, respectively. The phenotypes and CO
2production potentials of this yeast were also documented.This study has
confirmed the presence of different yeast species in the fermentation of teff dough and hinted the complex nature of Injera doughfermentation.
1. Introduction
Fermentation, degradation of organic compounds withoutnet oxidation by the microbial, is an important process inproduction and preservation of food. It is one of the oldestfood-processing technologies known, with some records dat-ing back to 6,000B.C. [1]. Locally with available rawmaterialsfrom plant or animal sources, people around the worldprepare fermented food and drink either naturally or by theaddition ofmicrobial starter cultures using traditional knowl-edge.Micro-organisms, by virtue of their metabolic activities,transform these raw materials both biochemically (i.e., thenutrients) and organoleptically (i.e., the taste/texture/odor,visual appearance) into appealing products that are culturally
acceptable to the maker and consumer, which at the sametime have improved shelf-life and safety [2, 3]. In addition,the unique group ofmicrobiota increases the levels of protein,vitamin, essential amino acids, fatty acids, digestibility, andpharmacological values. The importance of microbiota inmodern-day life is underlined by the wide spectrum offermented foods marketed in industrialized and developingcountries [2].This also demonstrates that these products playpotential role in securing the food demands of people indeveloping countries [4].
In developing countries food security is amajor challengefor many reasons. A traditional way of food productionpractice is among the major cause because it results inpoor yield, inefficient raw material processing, and loss due
HindawiInternational Journal of Food ScienceVolume 2019, Article ID 1291863, 7 pageshttps://doi.org/10.1155/2019/1291863
2 International Journal of Food Science
to poor management, spoilage, and contamination. Thismainly holds true regarding food production practices oftraditionally fermented foods. In general, in developingcountries, most of the traditional fermented foods are madeunder primitive conditions of spontaneous (uncontrolled)fermentations of nonsterile state which results in low yieldand poor quality food products [5]. The conditions, besideshaving a positive contribution to be important sources ofthe natural fermenting microorganisms, unfortunately, areexposing the fermented food products to contaminating andspoiling microorganisms that can survive the fermentationconditions [3] and the major sources of diarrheal disease [6]and food spoilage [7, 8], exacerbating poor socioeconomicconditions and taxing the nutritional requirements of thesociety.
Yeast are the most important microorganism in fer-mented foods and beverages such as bread, Injera, alcoholicbeverages, cheeses, and production of biologically importantproducts like insulin, enzyme, vitamins, and antibiotics [9,10]. Yeast are unicellular, eukaryotic, and polyphyletic organ-isms classified in the kingdom fungi. They are ubiquitousand commonly found on fruits, bulla, kocho, vegetables, andother plant materials [11]. However, yeast are highly involvedin food fermentations, but information on the dominantyeast species in African fermented foods still needs extraengagement especially in Ethiopian fermented teff dough[12, 13]. Thus, the identity of the proper yeast communitiesfor each fermented product is essential.
In Ethiopia most of the research conducted on traditionalfermented food primarily focuses on the determination ofthe microorganisms which are involved in the fermentation,spoilage, and contamination of the food. Unfortunately,limited research has been done on Injera, a fermented teffproduct of major importance in the nutrition and traditionof Ethiopians. Current research reports are largely limitedto only investigating microbial ecology of Injera employingonly phenotypic characterization [12, 14–17]. A very limitedliterature is available on identification of yeast in teff doughfermentation usingmolecular approach [18, 19].This researchwork aims to identify yeast using molecular approaches togain a rapid and accurate identification of yeast using inter-transcribed spacer (ITS) DNA of yeast [20]. We anticipatethis better understanding of yeast microbial communitiesfound in fermented teff dough will permit crafting of uniquecharacteristics of Injera to enhance its consumption andefficiency in production world-wide.
2. Materials and Methods
2.1. Sample Collection and Description of the Study Sites.Teff dough samples (two hundred gram each, 97 total) werecollected fromhotels, households and Injera baking microen-terprises in Addis Ababa, Ethiopia. Sample processing, labo-ratory isolation, and identification of yeast were carried out inthe Holeta Biotechnology Institute, Microbial BiotechnologyLaboratory. Molecular characterization was carried out at theMRC-ET Molecular Diagnostics Laboratory, Addis Ababa,Ethiopia and DNA sequencing was performed at Genewiz(South Plainfield, New Jersey, USA).
2.2. Isolation and Selection of Yeast. Samples of dough wereserial diluted by taking 10 g of dough from each sample intoseparate flasks with 90 mL sterile 0.1% peptone water andthen homogenized. From this preparation, 1mL was dilutedin to 9 ml sterile distilled water; then 0.1mL of appropriatedilution of separate samples was spread onto presolidifiedYeast Extract Glucose Chloramphenicol Bromophenol BlueAgar plates (i.e., yeast extract (5.0g/L), glucose (20.0g/L)Chloramphenicol (0.1g/L), Bromophenol blue (0.01g/L)) andincubated at 37∘C for 24h. After incubation, representativeyeast colonies were selected and subcultured using the samemedia three times to purify the isolates. Based on theircultural characteristics (colony size, colony color, and colonytexture) 155 yeast isolates were selected from each startingculture. Gas (CO
2) production from glucose was used as
a preliminary selection test criterion to further screen theisolates [21].
2.3. Production ofGas (CO2) fromGlucose. A total of 155 yeast
isolates were inoculated into tubes containing yeast extract(5.0g/L) glucose (20.0g/L) broth and were incubated at 37∘Cfor 24h. Production of gas (CO
2) from glucose was assayed
using 1.5% peptone water to which 1% glucose was 20.0g/Land 1mL of fresh Andrade indicator solution per 100 mLdistilled water was added.Themediumwas distributed in testtubes containing inverted Durham tubes. The medium wasautoclaved at 121∘C for 15 minutes and was then inoculatedwith the required cultures. Sterile paraffin wax of 2 ml wasoverlaid in each test tube to prevent the entry of oxygen. Alltubes were incubated at 37∘C and were examined daily for gasproduction for 7 days [22].
2.4. Molecular Characterization of Microbes
2.4.1. Genomic DNA Extraction. The genomic DNA of iso-lates was extracted using an Invisorb� Spin Genomic DNAExtraction kit according to the instruction of the manufac-turer [22, 23].
2.4.2. Amplification of ITS DNA of Yeast Isolates. Regions ofeach yeast internal transcribed spacers (ITS1 and ITS2) ofDNA extract was amplified using nested primers ITS1 andITS2 [16]. For ITS DNA region, PCR amplification reactionmixtures (50𝜇L) contained 1𝜇L of the extracted DNA, 1𝜇LdNTPs, 1𝜇L of each of primers ITS1 (-TCC GTA GGT GAACCT GCG G-) and ITS2 (-GCT GCG TTC TTC ATC GATGC-), 1𝜇L of Taq DNA polymerase (1.25 units/50 𝜇L) (Fer-mentas, St. Leon- Rot, Germany), and 5𝜇L PCR buffer. Thefinal reaction volume was adjusted to 50𝜇l by adding reverseosmosis purified water. The PCR cycle conditions include aninitial denaturation step at 95∘C for 10min, followed by 35cycles of denaturation at 94∘C for 30Sec, primer annealing at55∘C for 1min, and primer extension at 72∘C for 1min witha final extension at 72∘C for 5min [16]. PCR product thenwas separated by gel electrophoresis using a 3% Agarose geland 1𝜇L loading dye with 5𝜇L PCR products and stained withEthidium bromide for gel documentation.
International Journal of Food Science 3
2.4.3. Cloning and Sequencing of ITS DNA of Yeast. The PCRamplified a genomic region of interest (i.e., ITS DNA ofyeast) of each isolate was cloned into pGEMT EZ vector,transformed into XL1-blue cells, and inoculated onto platedLB medium containing 100𝜇g/mL ampicillin for selectionaccording to the manufacturer’s instructions (Promega Cor-poration). Isolates were grown for 16h at 37∘C with vigorousshaking in LB/Amp and the resulting plasmids were isolatedas described in the QIA quick Gel Extraction Kit. DNA wasthen sequenced by automated DNA sequencer (ABI model377; Applied Biosystems) at Genewiz (South Plainfield, NJUSA).
2.4.4. Phylogenetic Analysis. DNA sequences were edited,and consensus sequences were obtained using the Bioeditsoftware package http://www.mbio.ncsu.edu/BioEdit/bioedit.html. Final sequences were then aligned using CLUSTAL(version: 1.2.4) [24] for each of the sequences. The sequencesof yeast isolates of this study were then compared to thosein GenBank (National Centre for Biotechnology Informa-tion; https://blast.ncbi.nlm.nih.gov/Blast.cgi) using the BasicLocal Alignment Search Tool [25] for nucleotide sequences(blastn). Evolutionary analyses were conducted using theMaximum Likelihood method based on the Tamura-Neimodel by MEGA7 [26, 27].
2.4.5. Isolates Designation. Microbial isolates were desig-nated as follows: AAUYT for yeast isolate followed bynumbers and capital letters A, B, and C which represent therange of time of fermentation. A represents 48h, B represents60h, and C represents 72h of fermentation.
2.4.6. Data Analysis. All data were analyzed by using thestatistical data analysis software SPSS 20.0 version. And thephylogenetic tree construction was accomplished byMEGA7software.
3. Results
3.1. Isolation of Yeast and Gas Production from Glucose. Theyeast isolates (n=155) recovered were observed to have differ-ent features of colonialmorphology.Theyeast isolates showeddiverse culture characteristics with regard to color (white,gray pigmentation, or blue), shape (circular or irregular),edge (irregular or smooth), and elevation (flat or raised).
3.2. Production of Gas (CO2) from Glucose. Upon inoculating
the yeast isolates in Yeast Extract Glucose Broth (YEGB) andincubating at 25∘C for 24h, from a total of 155 yeast isolatesobtained from different fermenting teff dough, only 20 wereobserved with excellent potential of Gas production fromglucose (Table 1).
With the abundance of yeast in relation to samplesource most isolates were identified from household andthen hotel and followed by microenterprise. Kazachstaniabulderi were found from samples collected from house-hold; Saccharomyces cerevisiae and unidentified yeast isolateswere found from samples collected from hotel. Candidahumiliswere found as samples collected fromhouseholds and
Microenterprise whereas Pichia fermentans were found fromall sites.
The yeast isolates were also related to the age of fer-mentation inoculum used. Some of the yeast were old,some were fresh, and some were both. Candida humilis andSaccharomyces cerevisiae was found from samples havingfresh inoculum whereas Kazachstania bulderi were foundfrom samples containing old inoculum. Pichia fermentansand other unidentified yeast isolates were found from samplescontaining fresh and/or old inoculum.
3.3. Molecular Characterization of the Isolates. The PCRamplification product of 20 yeast isolates of the ITS DNAregion has indicated that the yeast isolates recovered in thisstudy have a fragment within 100 to 500bp (Figure 1) which isimportant for minimizing the number of isolates manageablefor sequencing.
3.3.1. Yeast ITS DNA Sequence Analyses. After all the rawsequences were edited, the BLAST result showed that only13 samples had significant similarity (98-100%) to Gen-Bank entries. Comparisons of ITS DNA sequences of theyeast isolates with yeast found in GenBank permitted theidentification of the yeast strains. The ITS DNA sequencesof the yeast isolates were used for the construction ofthe phylogenetic tree of yeast isolated from teff dough(Table 2). Sequence similarity was highest (100%) betweenAAUYT21B and strain of Pichia fermentans CBS: 2060. Ourresult indicated that AAUYT25A and AAUYT27A have 100%similarity with Pichia fermentans strain Pferm 62 08 02 05.AAUYT32A with Pichia fermentans CBS: 4807; AAUYT23C,AAUYT24C, and AAUYT28A with Candida humilis CBS:8195; AAUYT30B with Saccharomyces cerevisiae strain YAP1;and AAUYT26C and AAUYT34C with Pichia occidentalisstrain PMM08-2452Lwere found to have 99 % similarity. Onthe other hand,AAUYT31Awas shown to have 98% similaritywith Kazachstania bulderi CBS: 8638.
Accordingly, in this study the yeast isolates were iden-tified as belonging to four genera Candida, Kazachstania,Pichia, and Saccharomyces. The genus Candida consistedof one species, namely, Candida humilis CBS: 8195 (iso-lates AAUYT23B, AAUYT24C, and AAUYT28). The genusKazachstania contained one species called Kazachstaniabulderi (AAUYT31A), genus Pichia contained two species,namely, Pichia occidentalis (AAUYT26C and AAUYT34C),Pichia fermentans (AAUYT21B, AAUYT25A, AAUYT27A,and AAUYT32A), and genus Saccharomyces contained onespecies, Saccharomyces cerevisiae (AAUYT30B).
A phylogenetic tree was constructed from amplifiedand sequenced ITS DNA region of the 13 yeast isolates ofthose recovered from fermented teff dough in this study,which identified seven species. This phylogenetic groupingindicated that strains having similar sequences were clusteredinto four genera and nine strains (Figure 2).
The tree was generated through MEGA package version6 and was used to generate phylogenetic tree based on theTamura-Nei model for distance estimation and bootstrapanalyses with 1,000 replications with a cutoff point of 50shown next to the branches. The topology of the tree is with
4 International Journal of Food Science
Table 1: Morphological characteristics and gas production of the isolated yeast.
Isolates Species Colony MorphologyPigmentation Shape Elevation Size Gas prod ‘on
AAUYT21B Pichia fermentans White Circular Flat Large ++AAUYT23B Candida humilis White Circular Flat Large +++AAUYT24C Candida humilis White Circular Flat Medium +++AAUYT25A Pichia fermentans White Circular Flat Large +AAUYT26C Pichia fermentans Gray Irregular Raised Large +AAUYT27A Pichia fermentans White Irregular Raised Medium +AAUYT28A Candida humilis White Irregular Raised Large +AAUYT30B Saccharomyces cerevisiae Gray Irregular Raised Large ++AAUYT31A Kazachstania bulderi Blue Circular Flat Large +AAUYT32A Pichia fermentans Blue Circular Flat Large ++AAUYT33A Unidentified Blue Circular Flat Large +AAUYT34C Pichia fermentans White Circular Flat Large +AAUYT35B Unidentified White Circular Flat Large +AAUYT36B Unidentified Gray Irregular Raised Large +
AAU
BT22
AA
AUBT
21B
Ladd
er 1
Ladd
er 1
000b
p
AAU
BT30
B
AAU
BT28
A
AAU
BT29
B
AAU
BT25
A
AAU
BT27
AA
AUBT
26C
AAU
BT37
A
AAU
BT43
AA
AUBT
24C
AAU
BT23
B
AAU
BT36
B
AAU
BT39
AA
AUBT
40B
AAU
BT34
CA
AUBT
38A
AAU
BT44
A
AAU
BT33
AA
AUBT
41B
AAU
BT32
A
AAU
BT31
AA
AUBT
42A
AAU
BT35
B
500400300200
75
Figure 1: PCR amplification of yeast ITS DNA bands amplified by ITS1 and ITS2 yeast.
Table 2: Isolates on the basis of similarity to the partial ITS DNA sequence.
Isolates ID E value Identity Species AccessionAAUYT23B 0.0 99% Candida humilis CBS:8195 KY102138.1AAUYT24C 0.0 99% Candida humilis CBS:8195 KY102138.1AAUYT28A 0.0 99% Candida humilis CBS:8195 KY102138.1AAUYT31A 0.0 98% Kazachstania bulderi CBS: 8638 KY103628.1AAUYT21B 0.0 100% Pichia fermentans CBS:2060 KY104550.1AAUYT25A 0.0 100% Pichia fermentans strain Pferm 62 08 02 05 KU987883.1AAUYT27A 0.0 100% Pichia fermentans strain Pferm 62 08 02 05 KU987883.1AAUYT32A 0.0 99% Pichia fermentans CBS:4807 KY104537.1AAUYT26C 0.0 99% Pichia occidentalis strain PMM08-2452L KP132530.1AAUYT34C 0.0 99% Pichia occidentalis strain PMM08-2452L KP132530.1AAUYT30B 0.0 99% Saccharomyces cerevisiae strain YAP1 KY203910.1
International Journal of Food Science 5
Pichia fermentans strain Pferm 62_08_02_05 (KU987883.1)
Pichia fermentans CBS:2060 (KY104550.1)
Pichia fermentans CBS:2060 (AAUYT21B)
Pichia fermentans strain Pferm 62_08_02_05 (AAUYT27A)
Pichia fermentans strain Pferm 62_08_02_05 (AAUYT25B)
Pichia fermentans CBS:4807 (KY104537.1)
Pichia fermentans CBS:4807 (AAUYT32A)
Pichia occidentalis strain PMM08-2452L (KP132530.1)
Pichia occidentalis strain PMM08-2452L (AAUYT34C)
Pichia occidentalis strain PMM08-2452L (AAUYT26C)
Saccharomyces cerevisiae strain YAP1 (AAUYT30B)
Saccharomyces cerevisiae strain YAP1 (KY203910.1)
Kazachstania bulderi CBS: 8638 (AAUYT31A)
Kazachstania bulderi CBS: 8638 (KY103628.1)
Candida humilis CBS:8195 (KY102138.1)
Candida humilis CBS:8195 (AAUYT24C)
Candida humilis CBS:8195 (AAUYT28A)
Candida humilis CBS:8195 (AAUYT23C)
100
100
1004621
100
89
71
68
92
0.050
Figure 2: Phylogenetic tree of 13 yeast isolates from fermented teff dough using ITS DNA sequence. i.e., 13 yeast isolates were (AAUBT21B,AAUBT25B,AAUBT27A,AAUBT28A, AAUBT24C, AAUBT23C,AAUBT31A, AAUBT26C,AAUBT34C, AAUBT32AandAAUBT30B) and9 yeast accessions were from GenBank (KY102138.1, KY104888.1, KY104550.1, KU987883.1, KY103628.1, and KY102138.1 AND KY102138.1.).
similarity cutoff point of 50% and scale length of 0.050 andthe highest log likelihood (-430.59).The evolutionary historywas inferred by using the Maximum Likelihood method.
4. Discussion
This study made a definitive identity of 155 yeast isolatesand 20 of these were characterized for their potential in gasproduction [22]. Yeast isolates with good gas production werebelieved to be a strong fermenter, preferable for production ofInjera, and these were selected for molecular identification.
Molecular identification of yeast from fermented teffdough using sequence data identified was Pichia fermentans,Candida humilis, Kazachstania Saccharomyces cerevisiae,and Pichia occidentalis. Mogessie [17] has indicated thatyeast found in dough mainly contained Candida milleri,Rhodotorula mucilaginosa, Kluyveromyces marxianus, andPichia naganishii. Candida milleri was found from everyhousehold. This independent work supports the previousresults of Gifawesen and Abraham [14] who indicated thatthe dominant yeast of fermenting teff dough were species ofTorulopsis, Saccharomyces, Candida, and Pichia. Askal andKebede [10] have indicated that Candida humilis, Saccha-romyces cerevisiae,Cryptococcus tropicalis, and Saccharomycesexiguus were found from early stage to the end of teff doughfermentation. In this research also yeast were identified fromthe beginning of fermentation to the end.
Yeast was identified from all sample sources, i.e., house-hold, hotel, and microenterprises. Kazachstania bulderi were
found from household whereas Saccharomyces cerevisiae andunidentified yeastwas found in samples collected fromhotels.This variation may be due to personal hygiene and the sourceof the flour used for dough preparation. Unidentified yeastisolates were found from samples collected from both hotelsand households. Candida humilis have identified both sam-ples from households and microenterprise whereas Pichiafermentans were found from all sites. Yeast was also identifiedfrom samples with fresh and old inoculum and the selectedisolates were from each category, i.e., samples containingfresh and/ or old inoculum. Berhanu [15] also concluded thatyeast become the predominant group of organisms in ersho[12]. Saccharomyces spp. become abundant and is responsiblefor the rising of the dough. The yeast most prevalent in theersho belonged to the genera Candida and Pichia [12, 14].Saccharomyces spp. and Torulopsis spp. are the dominatinggroup of microorganisms after 50h of fermentation [28].Those identified yeast may involve in teff dough fermentationduring Injera preparation. Knowing the yeast found in teffdough at a species level is important for many aspects of thestarter culture in formulation for diverse and selected tastecharacteristics of teff Injera.
5. Conclusion
The study indicated that there is the involvement of differentyeast in teff dough fermentation (i.e., Pichia fermentans,Candida humilis, Kazachstania Saccharomyces cerevisiae, andPichia occidentalis). The identification of these isolates could
6 International Journal of Food Science
possibly contribute to the information needed for under-standing and verification of potential yeast involved in thecourse of teff dough fermentation.
Abbreviations
bp: Base pairCO2: Carbon dioxide
DNA: Deoxyribonucleic acidITS: Internal transcribed spacersPCR: Polymerase chain reactionRTA: Ready to prepareRNA: Ribonucleic acid𝜇l: Microliter.
Data Availability
The data used to support the findings of this study areavailable from the corresponding author upon request.
Conflicts of Interest
The authors declare that they have no competing interests.
Authors’ Contributions
Mr. Belay Tilahun conducted all the experiments and wrotethe manuscript. Mr. Andualem Bahiru, Dr. Anteneh Tes-faye, and Dr. Diriba Muleta coordinated the research work,designed portions of the experiments, and were involved inthe initial draft and the revision of themanuscript. Dr. ZewduTerefework participated in the molecular laboratory work,provided laboratory space, and revised the manuscript. Prof.GaryWessel performed theDNAcloning and sequencing andrevised the manuscript. All authors read and approved thefinal manuscript.
Acknowledgments
Mr. Belay thanks Dr. Abiy Zegeye, who have kindly assistedin the sequence analysis and bioinformatics part of theresearch. Mr. Belay also acknowledges the Holeta Agricul-tural Biotechnology Research Institute and the MRC-ETMolecular Diagnostics Laboratory, for support to accomplishthe molecular experiments. This study was supported by theInstitute of Biotechnology, Ministry of Science and Technol-ogy, Ethiopia, and MRC-ET Molecular Diagnostics, AddisAbaba, Ethiopia. The cost of sample collection was funded bythe Institute of Biotechnology Addis Ababa University. Thecost of laboratory consumables and laboratory payments wasfunded by the Ministry of Science and Technology, Ethiopia.MRC-ET Molecular Diagnostics also supported the cost ofsomemolecular laboratory reagents andDNAextraction kits.GMW and the DNA sequencing were supported by NIHgrant 9R01GM125071.
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